performance based seismic analysis of rc building ... based seismic analysis of rc building...
TRANSCRIPT
IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
_______________________________________________________________________________________
Volume: 04 Issue: 05 | May-2015, Available @ http://www.ijret.org 278
PERFORMANCE BASED SEISMIC ANALYSIS OF RC BUILDING
CONSIDERING THE EFFECT OF DUAL SYSTEMS
Md Zibran Pawaar1, Khalid Nayaz Khan
2, Syed Ahamed Raza
3
1M.Tech Student of Structural Engineering, Department of Civil Engineering, Ghousia College of Engineering,
Ramanagaram, Karnataka, India 2Associate Professor, Department of Civil Engineering, Ghousia College of Engineering, Ramanagaram, Karnataka,
India 3Assistant Professor, Department of Civil Engineering, Ghousia College of Engineering, Ramanagaram, Karnataka,
India
Abstract Due to the present increase in world population, people in this world tend to occupy available locations present in any zone which
also include zones falling in the high seismic zone categories. The buildings to be built in these seismic zones are more
susceptible to earthquakes for obvious reasons, and the buildings constructed in such zones must be analysed and designed for the unpredictable earthquakes with unpredictable magnitudes by various lateral load resisting systems such as shear walls, bracings,
tubular systems, coupled shear walls and even a combination of two load resisting systems called as dual systems. Present study
includes linear-static and non-linear static analysis with different shear wall arrangements on dual systems such as flat slabs and
shear walls & moment resisting frames and shear walls for different irregular plans using ETABS 9.7.4 software. Parameters
such as point displacements, base shears, pushover curves are studied.
Keywords: Dual Systems, Flat slabs, Pushover analysis, Shear walls.
--------------------------------------------------------------------***----------------------------------------------------------------------
1. INTRODUCTION
Presently there has been a tremendous increase in the
amount of tall storey's in modern localities and their
pressing concern is on the appearance of the structure which
is supposed to be tall slender. Along with these choices the
structure should be taken care of performance wise. Since
the structures being tall and slender are subjected to seismic
and wind loads. If the structure is not stiff enough to resist
the loads and vibrations caused. Therefore its important for
these structures to resist lateral forces along with vertical
forces. Dual systems have been recognized to resist lateral
loads effectively, since it’s a combination of two load resisting systems. Combination of moment resisting frames
along with shear walls and flat slabs with shear walls can be
used. Shear walls are vertical most commonly used
structures which act like vertical cantilevers to resist the
lateral loads effectively, such an element when combined
does give a good performance.
1.1 Dual Systems
The concept behind the dual system is to resist lateral load
by combining the two lateral load resisting systems. In these
systems the shape of the deformation will differ from those
in frames and wall systems, where effecting interlaced force
occur and change the shape of shear and moment diagrams.
One of the advantages of this combination is that the frames support the wall at the top and control their displacement.
Beside, the wall supports the frame at the bottom and
decreases their displacement.
1.2 Objectives
i. To compare various results such as, Base shear,
Point displacements and Story drift using linear
static and non-linear static analysis
ii. To know the effect of dual systems under seismic
forces by linear static and non-linear static analysis.
iii. To study and compare the performance of
geometrically irregular shaped structural rc
building models.
1.3 Analytical Methods
1.3.1 Linear Static Analysis
In a linear static analysis displacements, strains, stresses,
and reaction forces under the effect of applied loads are
calculated. It calculates the effects of steady loading
conditions on a structure, while ignoring inertia and damping effects, such as those caused by time-varying
loads. A static analysis can, however, include steady inertia
loads (such as gravity and rotational velocity), and time-
varying loads that can be approximated as static equivalent
loads (such as the static equivalent wind and seismic loads
commonly defined in many building codes).
1.3.2 Non-Linear Static Analysis (Pushover
Analysis)
Pushover analysis is defined as an analysis wherein a
mathematical model directly incorporating the nonlinear
load-deformation characteristics of individual components
IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
_______________________________________________________________________________________
Volume: 04 Issue: 05 | May-2015, Available @ http://www.ijret.org 279
and elements of the building shall be subjected to
monotonically increasing lateral loads representing inertia
forces in an earthquake until a „target displacement‟ is
exceeded. Target displacement is the maximum
displacement (elastic plus inelastic) of the building at roof
expected under selected earthquake ground motion.
2. ANALYTICAL MODELS CONSIDERED
2.1 Description of Building Structure
The buildings are modeled as a series of load resisting
elements. The lateral loads to be applied on the buildings are
based on the Indian standards. The study is performed for
seismic zone V as per IS 1893:2002. The frames are
assumed to be firmly fixed at the bottom and the soil
structure interaction is neglected.
Table 1: Model data of Building
Structure SMRF
No of Stories G+14
Storey Height 3m
Base Storey 3.5m
Type of Soil Medium Soil
Seismic Zone 5
Importance factor 1
Material Property
Grade of Concrete M30
Grade of Steel Fe415
Member Properties
Beam Size 300x450mm
Column Size 500x500mm
Shear wall Size 230mm
Thickness of Slab 150mm
Live Load 3 KN/m2
Live Load on Roof 2.5 KN/m2
Floor Finish 1 KN/m2
Model 1: Diaphragm discontinuity plan Modeled as Bare
Frame.
Model 2: E-shape Plan Modeled as bare Frame. Model 3: Diaphragm discontinuity plan modeled with flat
slabs and shear walls(at corners)
Model 4: E-shape plan modeled with flat slabs and shear
walls (at re-entrant corners).
Fig 1: Model 1
Fig 2 Model 2
Fig 3 Model 3
Fig 4 Model 4
IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
_______________________________________________________________________________________
Volume: 04 Issue: 05 | May-2015, Available @ http://www.ijret.org 280
3. RESULTS AND DISCUSSIONS
In this paper the results of all the building models are
presented. Analysis were carried out using ETABS and
different parameters studied such as Base shear, Point
displacement, and Pier Forces, the tables and figures are
shown below.
3.1 Base Shears
Fig 5 Base Shears For E Model.
Fig 6 Base Shears for Diaphragm Discontinuity Model.
3.2 Storey Drifts
Fig 7 Storey Drifts For E Model.
Fig 8 Storey drifts for Diaphragm Discontinuity Model
3.3 Point Displacements
Fig 9 Point displacements For E Model
Fig 10 Point Displacements For Diaphragm Discontinuity
IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
_______________________________________________________________________________________
Volume: 04 Issue: 05 | May-2015, Available @ http://www.ijret.org 281
3.4 Pushover Curves (Diaphragm Discontinuity
Models)
Fig 11 Pushover Curve For DD Bare Frame in X Dir.
Fig 12 Pushover Curve For DD Bare Frame in Y Dir.
Fig 13 Pushover Curve For DD FS & SW @ Corners in X
Dir.
Fig 14 Pushover Curve For DD FS & SW @ Corners in Y
Dir.
3.5 Pushover Curves (E Shaped Models)
Fig 15 Pushover Curve For "E" Bare Frame in X Dir.
Fig 16 Pushover Curve For "E" Bare Frame in Y Dir.
IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
_______________________________________________________________________________________
Volume: 04 Issue: 05 | May-2015, Available @ http://www.ijret.org 282
Fig 17 Pushover Curve For "E" FS & SW @ re-entrant
corners in X Dir
Fig 18 Pushover Curve For "E" FS & SW @ re-entrant
corners in Y Dir.
4 CONCLUSION
The above results show that the storey drifts are found
to be minimum in flat slabs and shear wall
combination in both E and diaphragm discontinuity
models.
Storey drift at al the levels in model E and diaphragm
discontinuity model are almost same but model E has
slightly less storey drift compared to diaphragm
discontinuity model.
When the point displacement are considered for these
four models, model E with combination of shear wall
at re-entrant corners and flat slabs are found to give
better results.
The base shear for dual system model for diaphragm
discontinuity is more than that of E model making E
model dual system better compared to diaphragm discontinuity model.
Non-linear curves both in longitudnal and transverse
direction.
REFERENCES
[1] Gayathri.H, Dr.H.Eramma, C.M.RaviKumar,
Madhukaran, 2014,"A Comparative Study On
Seismic Performance Evaluation Of Irregular
Buildings With Moment Resisting Frames And Dual
Systems"
[2] Navyashree K, Sahana T.S, 2014, "Use Of Flat Slabs In Multi-Storey Commercial Building Situated
In High Seismic Zone".
[3] Prof. K S Sable, Er. V A Ghodechor, Prof. S B
Kandekar, " Comparative Study of Seismic
Behavior of Multistory Flat Slab and Conventional
Reinforced Concrete Framed Structures"
[4] Nabin Raj .C, S.Elavenil, 2012, Presented a paper
on " Analytical Study on Seismic Performance of
Hybrid (DUAL) Structural System Subjected To
Earthquake"
[5] IS: 1893-2002 (part 1), “Indian Standard Criteria for
Earthquake Resistant Design of Structures”, fifth revision, Bureau of Indian Standards, New Delhi.
BIOGRAPHIES
M.Tech Student of Structural Engineering,
Department of Civil Engineering, Ghousia
College of Engineering, Ramanagaram,
Karnataka, India
Associate Professor, Department of Civil
Engineering, Ghousia College of
Engineering, Ramanagaram, Karnataka, India
Assistant Professor, Department of Civil
Engineering, Ghousia College of
Engineering, Ramanagaram, Karnataka,
India